JP5671488B2 - Solar cell module effectiveness monitoring system and monitoring method thereof - Google Patents

Description

  The present invention relates to a solar cell module efficacy monitoring system and a monitoring method thereof.

  In recent years, as global resources have decreased and eco-consciousness has increased, each country has focused on the development of alternative energy such as solar energy, wind energy, geothermal energy, hydro energy, etc. Among them, solar power generation has received the most attention. Yes. The amount of energy that reaches the daily surface of sunlight is about one-fourth of the world's oil reserves, a natural resource that cannot be exhausted. Photovoltaic power generation is clean, has no environmental pollution, does not deplete, is easy to combine with buildings, etc. In addition, coupled with the leap in semiconductor materials in recent years, the photoelectric conversion efficiency of sunlight continues to improve This has also led to wide application of solar cell modules (see, for example, Patent Document 1).

  However, environmental factors have a great influence on the power generation efficiency of the solar cell module. For example, factors such as climate, season, day and night affect the amount of solar radiation. Moreover, although it turned out that the dirt and dust on a solar cell module reduce electric power generation amount, it is difficult to discriminate | determine the relationship between dust accumulation and electric power generation efficiency fall. Furthermore, the power output of the solar cell module is also affected by the temperature of the module during actual use. The higher the module temperature, the lower the power output. For this reason, a system and method are required that can clearly identify the factors that decrease the power generation efficiency of the solar cell module.

  Moreover, although the development of the solar cell module technology has been progressed almost on the premise of improving the power generation efficiency of the solar cell module itself, there is no technology for evaluating the power generation efficiency of the solar cell module itself. Therefore, it is a main technical feature of the present invention to collect related data during operation of the solar cell module by using an existing sensor and evaluate the actual operation efficiency of the solar cell module through a specific calculation method. is there.

JP 2012-015412 A

  The main object of the present invention is to calculate the power generation loss of the solar cell module including the power loss due to dust accumulation, the power loss due to the operating temperature of the solar cell module, and the power loss due to the maximum power point tracking, and the comparison with the rated output It is an object to provide a solar cell module effectiveness monitoring system and method for calculating the power loss during actual operation of the solar cell module, reflecting the power generation efficiency in a timely manner, and issuing alarms and advice. .

  According to a first aspect of the present invention, there is provided a solar cell module efficacy monitoring system that provides a user with the power generation situation of a solar cell module by calculating and monitoring power loss due to dust accumulation of the solar cell module. A photovoltaic module, the reference module whose surface is always kept clean, the photovoltaic module, the evaluation module whose surface is covered with dust by the actual environment, and the reference module Are connected to the evaluation module, respectively, so as to follow the power of the two modules, respectively, and to keep the power output at the maximum point, the reference module and the evaluation module Connected to the PV communication recording device for recording the power generation results of the two modules, and the PV By being connected to the signal recording apparatus, efficacy monitoring system of the solar cell module comprising: the operation and display device, the calculating the power loss due to dust deposition of the evaluation module is provided.

  According to a second aspect of the present invention, there is provided a solar cell module efficacy monitoring system that provides a user with the power generation situation of a solar cell module by calculating and monitoring power loss due to the operating temperature of the solar cell module. A photovoltaic module, the reference module whose surface is always kept clean, the photovoltaic module, the evaluation module whose surface is covered with dust by the actual environment, and the reference module Including two maximum power point tracking devices that respectively track the power of the two modules and hold the power output at the maximum point, and two temperature sensors. Sensor communication record that records the operation temperature of the reference module and the evaluation module detected by two temperature sensors Connected to the reference module and the evaluation module, and connected to the PV communication recording device for recording the power generation results of the two modules, the sensor communication recording device, and the PV communication recording device. A solar cell module efficacy monitoring system comprising: an arithmetic display device that calculates a power loss due to an operating temperature of the evaluation module.

  According to the third aspect of the present invention, in the solar cell module efficacy monitoring system that provides the user with the power generation situation of the solar cell module by calculating and monitoring the power loss due to the maximum power point tracking of the solar cell module. A photovoltaic module, the reference module whose surface is always kept clean, the photovoltaic module, the evaluation module whose surface is covered with dust by the actual environment, The reference module and the evaluation module are connected to each other, follow the power of the two modules, respectively, and include two maximum power point tracking devices that hold the power output at the maximum point, and a sunshine meter, A sensor communication recording device that records the detected amount of solar radiation in the environment, and connected to the reference module and the evaluation module; The PV communication recording device that records the power generation results of the two modules, the sensor communication recording device, and the PV communication recording device are connected to calculate the power loss due to the maximum power point tracking of the evaluation module. A solar cell module efficacy monitoring system comprising: an arithmetic display device.

According to the fourth aspect of the present invention, there is provided a solar cell module efficacy monitoring system that provides a user with the power generation situation of the solar cell module by calculating and monitoring the power loss during actual operation of the solar cell module. A solar power generation module whose surface is always kept clean, a solar power generation module whose surface is covered with dust in the actual environment, and the reference Two maximum power point tracking devices connected to the module and the evaluation module, respectively tracking the power of the two modules and holding the power output at the maximum point, and connected to the reference module and the evaluation module A PV communication recording device that records the power generation results of the two modules, the reference module, and the evaluation Including two temperature sensors for detecting the operating temperature of the joule and a sunshine meter, and connected to the sensor communication recording device for recording the result detected by the sensor, the sensor communication recording device and the PV communication recording device, The power loss due to dust accumulation in the evaluation module, the power loss due to operation temperature, and the power loss due to maximum power point tracking are calculated, and the power loss during actual operation of the evaluation module is compared with the rated output of the reference module. A solar cell module efficacy monitoring system comprising: an arithmetic display device for calculating

According to the fifth aspect of the present invention, the power loss (Δp) during actual operation of the solar cell module is expressed by the following equation 1,
Power loss during actual operation of solar cell module (Δp)
= Rated output of solar cell module-(actually generated power of solar cell module + ΔPd + ΔPt + ΔPm) (Equation 1)
However, the rated output of the solar cell module is the rated output of the solar cell module (reference module) whose surface is kept clean,
The actual generated power of the solar cell module is the generated power of the solar cell module (evaluation module) whose surface is covered with dust,
ΔPd is the power loss due to the dust accumulation obtained from the measured generated power of the reference module and the evaluation module ,
ΔPt is the power loss due to operating temperature,
ΔPm is the power loss due to maximum power point tracking,
It is characterized by calculating from.

  According to the solar cell module efficacy monitoring system and the monitoring method thereof according to the present invention, the power generation of the solar cell module includes power loss due to dust accumulation, power loss due to operating temperature of the solar cell module, and power loss due to maximum power point tracking. The loss can be calculated, the power loss during actual operation of the solar cell module can be calculated by comparing with the rated output, the power generation efficiency can be reflected in a timely manner, and an alarm and advice can be issued.

It is a block diagram which shows schematic structure of the principal part in the efficacy monitoring system 1 of the solar cell module of embodiment concerning this invention. It is a block diagram which shows schematic structure of the principal part in the efficacy monitoring system 2 of the solar cell module of other embodiment concerning this invention. It is a block diagram which shows schematic structure of the principal part in the efficacy monitoring system 3 of the solar cell module of further another embodiment concerning this invention. It is a block diagram which shows schematic structure of the principal part in the efficacy monitoring system 4 of the solar cell module of other embodiment concerning this invention.

  Hereinafter, embodiments of a solar cell module efficacy monitoring system according to the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a block diagram showing a schematic configuration of a main part in an effect monitoring system 1 for a solar cell module according to an embodiment of the present invention. FIGS. 2 to 4 are block diagrams showing a schematic configuration of a main part in the solar cell module efficacy monitoring systems 2 to 4 of other embodiments according to the present invention. In addition, between each embodiment in this invention, about the component which has the same function, the same code | symbol is provided and the overlapping description is abbreviate | omitted.

  The solar cell module efficacy monitoring system 1 according to the embodiment of the present invention includes power loss due to dust deposition, power loss due to operating temperature of the solar cell module, and power loss due to maximum power point tracking. In addition to calculating, the power loss during actual operation of the solar cell module is calculated by comparing with the rated output, the power generation efficiency is reflected in a timely manner, and an alarm and advice are issued.

Hereinafter, with reference to FIG. 1, embodiment of the effectiveness monitoring system 1 of the solar cell module concerning this invention is described. The solar cell module efficacy monitoring system 1 according to this embodiment is
A reference module 11 which is a photovoltaic power module and whose surface is always kept clean;
An evaluation module 12 whose surface is covered with dust due to factors such as environment, climate, etc.
By being connected to the reference module 11 and the evaluation module 12, respectively, the maximum power point tracking device 13 that tracks the maximum power point of the two modules and holds the two modules to output the maximum power. , 14 and
A PV communication recording device 15 that is connected to the reference module 11 and the evaluation module 12 to read and record the power values of the two modules with a predetermined clamp meter;
By being connected to the reference module 11 and the evaluation module 12, respectively, temperature sensors 21 and 22 for detecting operation temperatures of the two modules,
A rain gauge 23 that detects the amount of rain in the environment, a particle detector 24 that detects the number of particles in the environment, a thermohygrometer 25 that detects temperature and humidity in the environment, and a wind speed and direction in the environment. A wind speed anemometer 26 that connects to a sunshine meter 27 that detects sunshine values in the environment, and a sensor communication recording device 28 for recording data detected by these sensors;
The sensor communication recording device 28 and the PV communication recording device 15 are connected to each other, and the power loss due to dust accumulation of the evaluation module 12 is determined based on the data from the sensor communication recording device 28 and the PV communication recording device 15. A calculation display device 16 for calculating;
The sensor communication recording device 28 and the PV communication recording device 15 are connected to each other, and based on the data from the sensor communication recording device 28 and the PV communication recording device 15, the power loss due to the operating temperature of the evaluation module 12 A calculation display device 29 for calculating the power loss due to the maximum power point tracking;
Power loss due to dust accumulation calculated by the calculation display device 16, power loss due to the operating temperature of the solar cell module calculated by the calculation display device 29, respectively connected to the calculation display device 16 and the calculation display device 29 A calculation display device 31 for calculating power loss during actual operation of the solar cell module based on power loss due to maximum power point tracking and related data such as actual generated power of the evaluation module 12 and rated output of the reference module 11; ,
By being connected to the calculation display devices 16, 29, 31 respectively, the alarm devices 17, 30 that issue an alarm and advice in response to each loss calculated by the calculation display devices 16, 29, 31 exceeding a specific value. , 32,
And a power supply 71 for supplying power to each part in the efficacy monitoring system 1 of the solar cell module.

  Next, how to use each part in the solar cell module efficacy monitoring system 1, power loss due to dust accumulation, power loss due to operating temperature of the solar cell module, power loss due to maximum power point tracking, and actual operation of the solar cell module The calculation of the power loss will be described.

  First, regarding the power loss due to dust accumulation, the solar cell module efficacy monitoring system 1 uses the reference module 11 and the evaluation module 12 to compare the influence of dust in the environment on the power generation efficiency of the solar cell module.

  The reference module 11 and the evaluation module 12 are connected to the maximum power point tracking devices 13 and 14, respectively, so that the two modules output the maximum power. The reference module 11 and the evaluation module 12 are also connected to the PV communication recording device 15, respectively. The power generation data of the reference module 11 and the evaluation module 12 is recorded in the PV communication recording device 15 and then sent to the calculation display device 16 for calculating the power loss due to dust accumulation. The calculation display device 16 calculates a power generation difference (including power generation amount, power generation efficiency, integrated power generation amount, etc.) between the evaluation module 12 covered with dust and the reference module 11.

  Some detection results (for example, detection results of module temperature, rainfall, fine particles, etc.) from each sensor recorded by the sensor communication recording device 28 are also sent to the calculation display device 16 to calculate power loss due to dust accumulation. Used for. How to use the module temperature, the rainfall amount, the detection result of the fine particles, etc., and the calculation of the power loss due to dust accumulation will be described later.

  The calculation result of the power generation difference is further sent to the alarm device 17. In the alarm device 17, based on the calculation result of the power generation difference calculated by the calculation display device 16, for example, monitoring is performed by an SPC (Statistical Process Control) statistical management method, and an alarm and advice are given in a timely manner. To emit.

  The solar cell module efficacy monitoring system 1 calculates and monitors the power loss due to the actual operating temperature of the solar cell module and the power loss due to the maximum power point tracking, and also has a function capable of issuing an alarm and advice in a timely manner. Also have.

  The detection results of each sensor recorded by the sensor communication recording device 28 are sent to the calculation display device 29. The power generation result of the solar cell module recorded by the PV communication recording device 15 is also sent to the calculation display device 29.

  The calculation display device 29 can calculate and monitor the power loss due to the actual operation temperature of the solar cell module and the power loss due to the maximum power point tracking. Explaining in detail, the power loss due to the actual operating temperature of the solar cell module in the system and the power loss due to the maximum power point tracking are calculated by calculation methods such as calculation, correction, regression, calibration, etc. for the sent data. That is.

  The power loss due to the operation temperature calculated as described above and the power loss due to the maximum power point tracking are further sent to the alarm device 30. In the alarm device 30, monitoring is performed by an SPC statistical management method, and an alarm and advice are issued in a timely manner.

  Further, the power loss due to dust accumulation calculated by the calculation display device 16, the power loss due to the operating temperature of the solar cell module calculated by the calculation display device 29, and the power loss due to maximum power point tracking are respectively supplied to the calculation display device 31. Sent. In the calculation display device 31, the power loss during actual operation of the solar cell module is calculated based on the respective data such as each loss, the actual generated power of the evaluation module 12 and the rated output of the reference module 11.

  The calculated power loss during actual operation of the solar cell module is further sent to the alarm device 32. In the alarm device 32, monitoring is performed by an SPC statistical process management method, and an alarm and advice are issued in a timely manner.

  In the present embodiment, the reference module 11 and the sunshine meter 27 may be connected to a cleaning device (not shown in the drawing) for keeping their surfaces clean. In addition, since the cleaning liquid used in the cleaning apparatus can be recycled and reused, the present invention also has a merit of water saving ecology.

  In the solar cell module efficacy monitoring system 1 according to the present invention, any data transmission between the components (data transmission from the sensors 21 to 27 to the communication recording devices 15 and 28, calculation from the communication recording devices 15 and 28). Including data transmission from the display devices 16, 29, data transmission from the arithmetic display devices 16, 29, 31 to the alarm devices 17, 30, 32, data transmission from the arithmetic display devices 16, 29 to the arithmetic display device 31, etc. ) Can be performed by wire, wireless or power line.

  Moreover, the power supply to each part in the efficacy monitoring system 1 of the solar cell module may be an internal power supply method or an external power supply method. The internal power feeding method is to feed back the power generated by the reference module 11 and the evaluation module 12 to the power supply 71 and further feed power from the power supply 71 to each part in the efficacy monitoring system 1 of the solar cell module. . Note that the power supply 71 may use an external power supply method in which power is supplied to the power supply 71 from the outside, and power is supplied from the power supply 71 to each part in the efficacy monitoring system 1 of the solar cell module.

  As described above, the embodiment of the present invention has been described using FIG. 1, but the present invention is not limited to the embodiment.

  For example, as shown in FIG. 2, you may have only one calculation display apparatus 33. FIG. The PV communication recording device 15 sends the power generation data of the reference module 11 and the evaluation module 12 and the detection data of each sensor recorded by the communication recording device 15 to the calculation display device 33. In the calculation display device 33, power loss due to dust accumulation The power loss due to the operating temperature of the solar cell module and the power loss due to the maximum power point tracking are calculated, respectively, and based on related data such as each loss, the actual generated power of the evaluation module 12, and the rated output of the reference module 11. The power loss during actual operation of the solar cell module is calculated.

  Here, an alarm device 34 may be connected to the calculation display device 33. In the alarm device 34, monitoring is performed by an SPC statistical management method, and an alarm and advice are issued in a timely manner.

  Alternatively, as shown in FIG. 3, three calculation display devices 35, 36, and 37 may be provided. The PV communication recording device 15 sends the power generation data of the reference module 11 and the evaluation module 12 and the detection data of each sensor recorded by the communication recording device 15 to the calculation display devices 35, 36, and 37, respectively. In the calculation display devices 35, 36, and 37, the power loss due to dust accumulation, the power loss due to the operating temperature of the solar cell module, and the power loss due to the maximum power point tracking are respectively calculated. The calculated losses are further sent to the calculation display device 38. In the calculation display device 38, based on the power loss due to dust accumulation, the power loss due to the operating temperature of the solar cell module, and the power loss due to maximum power point tracking, the actual generated power of the evaluation module 12 and the rated output of the reference module 11 Based on the related data, etc., the power loss during actual operation of the solar cell module is calculated.

  Here, an alarm device 39 may be connected to the calculation display device 38. In the alarm device 39, monitoring is performed by an SPC statistical process management method, and an alarm and advice are issued in a timely manner.

  The calculation display devices 35, 36, and 37 for calculating the power loss due to dust deposition, the power loss due to the operating temperature of the solar cell module, and the power loss due to the maximum power point tracking in the embodiment of FIG. 3 are shown in FIG. As shown, they may be connected to different alarm devices 40, 41, 42, respectively. The alarm devices 40, 41, and 42 issue alarms and advice in a timely manner based on power loss due to dust accumulation, power loss due to operating temperature of the solar cell module, and power loss due to maximum power point tracking.

  The above-described embodiments of FIGS. 1 to 4 are merely illustrative of the embodiments of the present invention. The number of the arithmetic display device and the alarm device according to the present invention can be arbitrarily combined. The present invention is not limited to the above-described embodiment, and those having ordinary knowledge in the technical field of the present invention should be able to conceive various changes within the technical scope to which the present invention belongs.

  Hereinafter, the effect monitoring method of the solar cell module according to the present invention will be described.

  The calculation method of the power loss due to dust deposition, the power loss due to the operating temperature of the solar cell module, and the power loss due to maximum power point tracking will be described with reference to the configuration of the apparatus according to the embodiment of the present invention.

The power loss due to dust accumulation is denoted by ΔPd, the power loss due to the operating temperature of the solar cell module is denoted by ΔPt, and the power loss due to the maximum power point tracking is denoted by ΔPm. The power loss (Δp) during actual operation of the solar cell module is obtained from the following equation 1.
Power loss during actual operation of solar cell module (Δp)
= Rated output of solar cell module-(actually generated power of solar cell module + ΔPd + ΔPt + ΔPm) (Equation 1)
In Equation 1, the rated output of the solar cell module is the generated power of the solar cell module detected based on the ASTM E1036 standard when the solar cell module is in a standard test state (temperature 25 ° C., solar radiation intensity 1,000 W / m ² ). is there. In the present invention, the rated output provided by the manufacturer of the photovoltaic module is used as the rated output of the solar cell module. The actual generated power of the solar cell module is generated power in a state where the evaluation module 12 is actually used, that is, in a state where the surface is covered with dust.

  The power loss ΔPd due to dust accumulation is obtained by a calculation method in which the generated power of the evaluation module 12 is subtracted from the generated power of the reference module 11.

  Note that the rain gauge 23 and the particulate detector 24 are also used to determine whether the surface is really covered with dust (the degree of dust accumulation), or whether the power generation loss is caused by a system abnormality or other factors. . If the amount of particles detected by the particle detector 24 is high, the power loss due to dust accumulation should also increase. On the other hand, if the rainfall value detected by the rain gauge 23 is high, the surface of the solar cell module has been cleaned and cleaned, so that power loss due to dust accumulation should be reduced. If the tendency is different from the above, it can be presumed that the power generation amount is influenced by a factor that is not dust accumulation, and therefore it is determined that the system needs to be inspected or confirmed.

  When covered with dust, the temperature of the solar cell module decreases, so the temperature difference between the reference module 11 and the evaluation module 12 detected by the temperature sensors 21 and 22 is used to assist the judgment of the degree of dust accumulation. You can also.

Next, calculation of the power loss Pt due to the operating temperature of the solar cell module will be described. When the solar cell module receives sunlight, the temperature gradually increases. As the temperature of the solar cell module increases, the power loss ΔPt due to the operation temperature of the solar cell module decreases from the following equation 2 in order to reduce the amount of power generation. The power generation loss under the condition of C can be compared and calculated.
ΔPt = P × [{α (T−25)} / {1 + α (T−25 )}] (Expression 2)
In Equation 2, P is the generated power of the evaluation module 12 recorded by the PV communication recording device 15, α is the temperature coefficient of the solar cell module, and T is the operating temperature of the evaluation module 12 detected by the temperature sensor 22. .

  The operating temperature of the solar cell module is detected by the temperature sensor 22. The temperature sensor 22 may be installed at an arbitrary place on the front surface or the back surface of the evaluation module 12, and the number of the temperature sensors 22 is not limited to one and may be plural. When there are a plurality of temperature sensors 22, the average value of the operation temperatures detected by the plurality of temperature sensors is set as the operation temperature of the module.

  However, since the temperature sensor 22 is installed on the front surface or the back surface of the solar cell module, there is a possibility that a difference occurs between the temperature detected by the temperature sensor 22 and the actual operation temperature of the solar cell module when wind hits the temperature sensor 22. is there. Since the temperature and humidity in the environment may also cause a difference between the temperature detected by the temperature sensor 22 and the actual operation temperature of the solar cell module, the solar cell using the temperature / humidity meter 25 and the wind speed / direction meter 26 is used. The operating temperature of the module can also be corrected.

  The amount of sunlight energy that can be converted by the solar cell module is determined by the sunlight intensity of sunlight and the temperature of the solar cell module. The maximum power point tracker was developed because the power output of the solar cell module is also different under different operating environments and conditions. The maximum power point follower can follow the maximum power point of the solar cell module when the sunshine intensity changes, and can maximize the power output of the solar cell module even when part of the solar cell module is cut off. It can be done.

  In the present invention, by using the maximum power point tracking devices 13 and 14, the maximum power point of the reference module 11 and the evaluation module 12 is tracked and held so that the reference module 11 and the evaluation module 12 can output the maximum power at any time. To do. However, when the sunlight is interrupted instantaneously, the power of the solar cell module is reduced, but the maximum power point tracking device may not be able to track the maximum power point, causing power loss due to the maximum power point tracking. Therefore, another feature of the present invention is that power loss due to maximum power point tracking can be calculated.

  The power loss due to the maximum power point tracking in the present invention is calculated by comparing the power generation data of the solar cell module with the sunshine value to calculate the power loss ΔPm by the maximum power point tracking. More specifically, using the current and power value of the evaluation module 12 recorded by the PV communication recording device 15 and the sunshine value detected by the sunshine meter 22, linear regression of the current and sunshine value by regression analysis which is a statistical method. Seeking a relationship. After removing abnormal values (for example, ± 5%) above and below the regression line, and further obtaining a linear regression relationship between the power and the sunshine value, an upper limit value and a lower limit value (for example, from the regression line of the power and the sunshine value) , ± 10%), and the value exceeding the upper and lower limits of the regression line is defined as the power loss due to maximum power point tracking.

  As described above, according to the present invention, when a conventional solar cell module is actually operated, it is possible to solve the problem that it is not possible to effectively determine whether or not the effect has been achieved like the theoretical effect.

  The present invention uses a reference module and an evaluation module to detect power generation data of a solar cell module and each sensor (for example, a temperature sensor, a rain gauge, a particulate detector, a temperature / humidity meter, a wind speed anemometer, a sunshine meter, etc.). Collect data, calculate power loss due to dust accumulation, power loss due to operating temperature of solar cell module, and power loss including power loss due to maximum power point tracking. It calculates the power loss during actual operation of the battery module, reflects the power generation efficiency in a timely manner, and issues alarms and advice.

  Further, the actual operation of the solar cell module is compared with the rated output while utilizing the power loss due to dust accumulation, the power loss due to the operating temperature of the solar cell module, and the power loss due to the maximum power point tracking, which is a feature of the present invention. According to the specific calculation method that can calculate the power loss at the time, reference information of operation and maintenance (for example, whether it needs to be cleaned, whether the material has deteriorated, and the power generation efficiency is lower than expected) If so, analysis report information including whether maintenance or solar cell module needs to be replaced can be provided to the power station personnel on a regular basis. Furthermore, if it is inconsistent with the contents of the contract signed with the manufacturer of the solar cell module, it can be used as evidence of the right to seek compensation.

  1, 2, 3, 4 ... Solar cell module effectiveness monitoring system, 11 ... Reference module, 12 ... Evaluation module, 13, 14 ... Maximum power point tracking device, 15 ... PV communication recording device, 16, 29,31,33,35-38..Calculation display device, 17, 30, 32, 34, 39-42 .... Alarm device, 21,22 ... Temperature sensor, 23 ... Rain gauge, 24 ... Particle detection 25 ... temperature / humidity meter, 26 ... wind speed anemometer, 27 ... sunshine meter, 28 ... sensor communication recorder, 71 ... power supply.

Claims (19)

A solar cell module effectiveness monitoring system that provides the user with the power generation situation of the solar cell module by calculating and monitoring power loss due to dust accumulation in the solar cell module,
A photovoltaic module, whose reference surface is always kept clean,
An evaluation module whose surface is covered with dust by the actual environment, which is a photovoltaic power generation module,
Two maximum power point tracking devices that respectively follow the power of the two modules by being connected to the reference module and the evaluation module, and hold their power output at the maximum point,
PV communication recording device that records the power generation results of the two modules by being connected to the reference module and the evaluation module;
An arithmetic display device that calculates power loss due to dust accumulation of the evaluation module by being connected to the PV communication recording device;
A solar cell module efficacy monitoring system comprising:   The solar cell module performance monitoring system according to claim 1, further comprising a rain gauge, wherein the rain gauge is used to assist calculation of power loss due to dust accumulation.   The solar cell module efficacy monitoring system according to claim 1, further comprising a particulate detector, wherein the particulate detector is used to assist in calculating power loss due to dust accumulation. A solar cell module effectiveness monitoring system that provides the user with the power generation situation of the solar cell module by calculating and monitoring the power loss due to the operating temperature of the solar cell module,
A photovoltaic module, whose reference surface is always kept clean,
An evaluation module whose surface is covered with dust by the actual environment, which is a photovoltaic power generation module,
Two maximum power point tracking devices that respectively follow the power of the two modules by being connected to the reference module and the evaluation module, respectively, and hold the power output at the maximum point;
A sensor communication recording device that includes two temperature sensors, and records operation temperatures of the reference module and the evaluation module detected by the two temperature sensors;
PV communication recording device that records the power generation results of the two modules by being connected to the reference module and the evaluation module;
An arithmetic display device that calculates power loss due to an operating temperature of the evaluation module by being connected to the sensor communication recording device and the PV communication recording device;
A solar cell module efficacy monitoring system comprising:   5. The solar cell module efficacy monitoring system according to claim 4, wherein the sensor communication recording device further includes a thermo-hygrometer, and the operation temperature of the reference module and the evaluation module is corrected by the thermo-hygrometer.   5. The effect of the solar cell module according to claim 4, wherein the sensor communication recording device further includes a wind speed anemometer, and corrects power loss due to an operating temperature of the reference module and the evaluation module by the wind speed anemometer. Monitoring system. A solar cell module effectiveness monitoring system that provides the user with the power generation situation of the solar cell module by calculating and monitoring the power loss due to the maximum power point tracking of the solar cell module,
A photovoltaic module, whose reference surface is always kept clean,
An evaluation module whose surface is covered with dust by the actual environment, which is a photovoltaic power generation module,
Two maximum power point tracking devices connected to the reference module and the evaluation module, respectively tracking the power of the two modules and holding the power output at the maximum point;
A sensor communication recording device that includes a sunshine meter and records the amount of solar radiation in the environment detected by the sunshine meter;
PV communication recording device that records the power generation results of the two modules by being connected to the reference module and the evaluation module;
An arithmetic display device that calculates power loss due to maximum power point tracking of the evaluation module by being connected to the sensor communication recording device and the PV communication recording device;
A solar cell module efficacy monitoring system comprising: A solar cell module efficacy monitoring system that provides the user with the power generation situation of the solar cell module by calculating and monitoring the power loss during actual operation of the solar cell module,
A photovoltaic module, whose reference surface is always kept clean,
An evaluation module whose surface is covered with dust by the actual environment, which is a photovoltaic power generation module,
Two maximum power point tracking devices connected to the reference module and the evaluation module, respectively tracking the power of the two modules and holding the power output at the maximum point;
PV communication recording device that records the power generation results of the two modules by being connected to the reference module and the evaluation module;
A sensor communication recording device that includes two temperature sensors for detecting the operation temperature of the reference module and the evaluation module and a sunshine meter, and records a result detected by the sensor;
By connecting to the sensor communication recording device and the PV communication recording device, power loss due to dust accumulation of the evaluation module, power loss due to operation temperature, and power loss due to maximum power point tracking are calculated, respectively, and the reference module A calculation display device that calculates power loss during actual operation of the evaluation module by comparison with the rated output of
A solar cell module efficacy monitoring system comprising:   9. The solar cell module efficacy monitoring system according to claim 8, wherein one or a plurality of the calculation display devices are provided.   10. The solar cell module according to claim 1, further comprising an alarm device, wherein an alarm and advice are issued in a timely manner when the power loss calculated by the calculation display device exceeds a specific value. Efficacy monitoring system.   The solar cell module efficacy monitoring system according to any one of claims 1 to 9, wherein transmission of all data between the constituent elements is performed by any one of wired, wireless, and power lines. .   The solar cell module efficacy monitoring system according to any one of claims 1 to 9, wherein a cleaning device is further connected to the reference module.   The solar cell module efficacy monitoring system according to claim 12, wherein the cleaning liquid used in the cleaning device is recycled and reused.   The power supply device further includes a power supply unit connected to the reference module and the evaluation module, and the power generation by the reference module and the evaluation module is fed back to the power supply device, and further from the power supply device to the effect monitoring system of the solar cell module. 10. The solar cell module efficacy monitoring system according to claim 1, wherein power is supplied to each unit. 11.   A power supply device connected to an external power supply is further provided, and the power supply device is supplied with power from the external power supply, and further, the power supply device is supplied with power to each part of the effect monitoring system of the solar cell module. Item 10. The solar cell module efficacy monitoring system according to any one of Items 1 to 9. The power loss (Δp) during actual operation of the solar cell module is expressed by the following formula 1,
Power loss during actual operation of solar cell module (Δp)
= Rated output of solar cell module-(actually generated power of solar cell module + ΔPd + ΔPt + ΔPm) (Equation 1)
However, the rated output of the solar cell module is the rated output of the solar cell module (reference module) whose surface is kept clean,
The actual generated power of the solar cell module is the generated power of the solar cell module (evaluation module) whose surface is covered with dust,
ΔPd is the power loss due to the dust accumulation obtained from the measured generated power of the reference module and the evaluation module ,
ΔPt is the power loss due to operating temperature,
ΔPm is the power loss due to maximum power point tracking,
A method for monitoring the effectiveness of a solar cell module, characterized by:   The method for monitoring the effectiveness of a solar cell module according to claim 16, wherein the power loss ΔPd due to dust accumulation is obtained by a calculation method of subtracting the generated power of the evaluation module from the generated power of the reference module. The power loss ΔPt due to the operating temperature of the module is expressed by the following formula 2,
ΔPt = P × [{α (T−25)} / {1 + α (T−25 )}] (Expression 2)
Where P is the generated power of the evaluation module,
α is the temperature coefficient of the module,
T is the operating temperature of the evaluation module,
It calculates from these. The efficacy monitoring method of the solar cell module of Claim 16 characterized by the above-mentioned. The power loss ΔPm due to the maximum power point tracking is
A regression analysis, which is a statistical method, uses the current and power of the evaluation module detected by the PV communication recording device provided in the efficacy monitoring system for the solar cell module according to claim 8 and the sunshine value detected by the sunshine meter. Find the linear regression relationship between the current and the sunshine value, then the linear regression relationship between the power and the sunshine value, determine the upper and lower limits from the regression line of the power and the sunshine value, and determine the upper and lower limits of the regression line The method for monitoring the effectiveness of a solar cell module according to claim 16, wherein the numerical value exceeds the value.

Images